Flexible and scalable monitoring systems for industrial machines

ABSTRACT

A flexible monitoring system and corresponding methods of use are provided. The system can include a base containing backplane, and one or more circuits communicatively coupled to the backplane. The circuits can be designed with a common architecture that is programmable to perform different predetermined functions, such as input, output, and processing. By separating functions of the flexible monitoring system into different circuits, new implementations of the flexible monitoring system can be rapidly developed by arranging already created components in different combinations. Multiple bases can also be communicatively coupled in a manner that establishes a common backplane between respective bases. Accordingly, implementations of the flexible monitoring system distribute combinations of circuits across different bases, providing flexible deployment options.

BACKGROUND

Many industries, such as hydrocarbon refining and power generation, can rely heavily upon operation of machinery, and in some instances, continuous operation of machinery. In these environments, failure of one or more machines can incur significant costs due to repair expenses as well as loss of production and potential injury to workers. Given these risks, it can be common to monitor certain operating parameters of one or more machine components. Measurements of the operating parameters can provide an indication of the mechanical condition of a machine component, allowing preventative maintenance (e.g., repair, replacement, etc.) to be performed on the machine component prior to failure. This monitoring can provide one or more long term benefits, such as lower production costs, reduced equipment down time, improved reliability, and enhanced safety.

SUMMARY

In general, systems and methods are provided for protection and/or condition monitoring of machines, such as industrial machines.

In one embodiment, a system is provided and it can include a backplane, a first input circuit, a second input circuit, and a protection processing circuit. The backplane can be configured to couple to a plurality of circuits. The backplane can also be configured to receive monitoring data from at least one circuit coupled to the backplane. The first input circuit can be coupled to the backplane and it can be configured to receive a first sensor signal from a first sensor. The first sensor signal can represent first monitoring data including measurements of a first operating parameter of a first machine component. The first input circuit can also be configured to transmit the first monitoring data to the backplane. The second input circuit can be coupled to the backplane and it can be configured to receive a second sensor signal from a second sensor, different from the first sensor. The second sensor signal can represent second monitoring data including measurements of a second operating parameter of a second machine component. The second input circuit can also be configured to transmit the second monitoring data to the backplane. The protection processing circuit can be coupled to the backplane and it can be configured to retrieve first selected monitoring data from the backplane in response to receipt of a first protection command. The first selected monitoring data can include at least a portion of at least one of the first and second monitoring data. The protection processing circuit can also be configured to determine a value characterizing the first selected monitoring data. The protection processing circuit can also be configured to transmit the determined value to the backplane.

In another embodiment, the system can include a system interface circuit coupled to the backplane. The system interface circuit can be configured to transmit the first protection command to the backplane. The first protection command can identify the first selected monitoring data for retrieval by the protection processing circuit.

In another embodiment, the first protection command can include one or more set points corresponding to respective alarm conditions for the first selected monitoring data. The protection processing circuit can be further configured to determine a status for the first selected monitoring data based upon a comparison of the set point to the determined value, and to transmit the determined status to the backplane.

In another embodiment, the first selected monitoring data can include at least a portion of the first monitoring data and the second monitoring data.

In another embodiment, the system can include a first output circuit coupled to the backplane. The first output circuit can be configured to retrieve the determined value from the backplane, and to output a process control signal including a current or a voltage that is proportional to the determined value with reference to a predetermined scale.

In another embodiment, the system can include a second output circuit coupled to the backplane. The second output circuit can be configured to retrieve second monitoring data from the backplane in response to receipt of a second protection command, and output the retrieved second monitoring data to at least one of a data storage device and a display. The second protection command can be transmitted to the backplane by the system interface circuit and the second protection command can identify the second monitoring data. The second monitoring data can include at least a portion of at least one of the first operating parameter measurements and the second operating parameter measurements.

In another embodiment, the backplane can be a passive backplane.

In an embodiment, a system is provided and it can include a backplane and a condition processing circuit. The backplane can be configured to communicatively couple to a plurality of circuits and to receive monitoring data from at least one circuit coupled to the backplane. The monitoring data can include at least one of measurements of an operating parameter of a machine component acquired by a sensor and at least one value characterizing the monitoring data at a status time. The condition processing circuit can be coupled to the backplane and it can be configured to retrieve a first selected portion of the monitoring data from the backplane in response to receipt of a conditioning command from a first network. The condition processing circuit can also be configured to transmit the retrieved first selected portion of the monitoring data to the first network. The condition processing circuit can be prohibited from transmitting information to the backplane.

In another embodiment, the monitoring data can include a status of the measured operating parameter at a status time based upon the determined value. The conditioning command can be operative to cause the condition processing circuit to retrieve the status from the backplane, determine that the retrieved status matches a predetermined status, and retrieve at least one of first portion of the operating parameter measurements corresponding to a first predetermined time duration prior to the status time and a second portion of the operating parameter measurements corresponding to a second predetermined time duration after the status time.

In another embodiment, the first network is not communicatively coupled to a second network. The second network can be in communication with a control system operative to control the operating parameter of the machine component.

In another embodiment, the system includes a system interface circuit coupled to the backplane. The system interface circuit can be configured to receive a protection command from the second network, and to transmit the protection command to the backplane.

In another embodiment, the system can include a protection processing circuit coupled to the backplane. The protection processing circuit can be configured to retrieve the operating parameter measurements from the backplane in response to receipt of the protection command. The protection processing circuit can also be configured to determine the value based upon the retrieved operating parameter measurements, and to transmit the determined value to the backplane.

In another embodiment, the backplane can be a passive backplane.

Methods for monitoring a machine are also provided. In one embodiment, the method can include communicatively coupling a first input circuit and a second input circuit to a backplane. The method can also include transmitting, by the first input circuit, first monitoring data to the backplane. The first monitoring data can represent measurements of a first operating parameter of a first machine component acquired by a first sensor. The method can further include transmitting, by the second input circuit, second monitoring data to the backplane. The second monitoring data can represent measurements of a second operating parameter of a second machine component acquired by a second sensor, different from the first sensor. The method can additionally include communicatively coupling a protection processing circuit to the backplane. The method can further include retrieving, by the protection processing circuit, first selected monitoring data from the backplane in response to receipt of a first protection command. The first selected monitoring data can include at least a portion of at least one of the first and second monitoring data. The method can also include determining, by the protection processing circuit, a value characterizing the first selected monitoring data. The method can further include transmitting, by the protection processing circuit, the determined value to the backplane.

In another embodiment, the method can include communicatively coupling a system interface circuit to the backplane, and transmitting the first protection command to the backplane. The first protection command can identify the first selected monitoring data for retrieval by the protection processing circuit.

In another embodiment, the first protection command can include a set point corresponding to an alarm condition for the first selected monitoring data. The method can further include determining, by the protection processing circuit, a status for the first selected monitoring data based upon the set point, and transmitting, by the protection processing circuit, the determined status to the backplane.

In another embodiment, the method can include communicatively coupling an output circuit to the backplane. The method can also include retrieving, by the output circuit, second monitoring data from the backplane in response to receipt of a second protection command. The method can further include outputting, by the output circuit, the retrieved second monitoring data to an internal network in communication with a machine control system operative to control the first and second operating parameters of the first and second machine components. The second protection command can be transmitted to the backplane by the system interface circuit and it can identifies the second monitoring data. The second monitoring data can include at least a portion of at least one of the first operating parameter measurements and the second operating parameter measurements.

In another embodiment, the method can include communicatively coupling a condition processing circuit to the backplane and to a first network. The method can further include retrieving, by the condition processing circuit, third selected monitoring data from the backplane in response to receipt of a conditioning command from an external network, different from the internal network. The third selected monitoring data can include at least a portion of at least one of the first monitoring data, the second monitoring data, and the determined status. The method can further include transmitting, by the condition processing circuit, the retrieved third selected monitoring data to the external network. The condition processing circuit can be prohibited from transmitting information to the backplane.

In another embodiment, the conditioning command can be operative to cause the condition processing circuit to retrieve a status for the first monitoring data at a status time from the backplane, determine that the retrieved status matches a predetermined status, and retrieve a portion of at least one of the first and second operating parameter measurements occurring adjacent in time to the status time.

In another embodiment, the operating parameter can include at least one of vibration, position, speed, direction of motion, and eccentricity.

DESCRIPTION OF DRAWINGS

These and other features will be more readily understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

FIG. 1A is a diagram illustrating one exemplary embodiment of an operating environment containing an existing monitoring system;

FIG. 1B is a diagram illustrating one exemplary embodiment of a backplane of the monitoring system of FIG. 1A;

FIG. 2A is a diagram illustrating one exemplary embodiment of an operating environment containing a flexible monitoring system configured to monitor a machine;

FIG. 2B is a diagram illustrating exemplary embodiments of circuits configured for use with the flexible monitoring system of FIG. 2A;

FIG. 3 is a diagram illustrating one exemplary embodiment of a backplane of the flexible monitoring system of FIG. 2A;

FIG. 4A is a diagram illustrating one exemplary embodiment of a relatively flexible large size monitoring system configured for protection monitoring and condition monitoring;

FIG. 4B is a diagram illustrating one exemplary embodiment of a medium size flexible monitoring system configured for protection monitoring;

FIG. 4C is a diagram illustrating one exemplary embodiment of a small size flexible monitoring system configured for protection monitoring;

FIG. 5 is a diagram illustrating one exemplary embodiment of a flexible monitoring system including three bases communicatively coupled by bridge circuits and having input circuits, output circuits, a protection processing circuit, and a condition processing circuit distributed between the three bases;

FIG. 6 is a diagram illustrating one exemplary embodiment of a flexible monitoring system including two bases communicatively coupled by bridge circuits and having input circuits and output circuits coupled to one base and protection processing circuits and condition processing circuits coupled to the other base;

FIG. 7 is a diagram illustrating one exemplary embodiment of a flexible monitoring system including five bases communicatively coupled by bridge circuits and having input circuits and output circuits coupled to multiple small bases and protection processing circuits and condition processing circuits coupled to a larger base for efficiency; and

FIG. 8 is a flow diagram illustrating one exemplary embodiment of a method for monitoring a machine.

It is noted that the drawings are not necessarily to scale. The drawings are intended to depict only typical aspects of the subject matter disclosed herein, and therefore should not be considered as limiting the scope of the disclosure.

DETAILED DESCRIPTION

Industrial machinery, such as wind turbines, can be monitored by monitoring systems to ensure operation within acceptable tolerances. In general, machine monitoring can include measuring operating parameters of one or more of the machine components, determining whether the machine components are operating properly from the operating parameter measurements, and issuing warnings if a machine component is determined to be operating improperly. These warnings can allow corrective action to taken in advance of machine failure, providing benefits such as lower production costs, reduced equipment down time, improved reliability, and/or improved safety.

However, existing monitoring systems can be relatively inflexible. As an example, manufacturers can make different types of monitoring systems that have different capabilities, referred to as models or implementations. Different monitoring system implementations can include components, such as inputs, outputs, and processors, that are designed for use only with their specific implementation. The inability to share components between different monitoring system implementations can require development of new components for each new implementation, rather than utilizing already created components and can slow the deployment of new monitoring system implementations. In another example, different monitoring system implementations can require more resources (e.g., spare hardware and software, trained personnel, etc.) to manage, as each can include different specialized components that can behave differently. Accordingly, embodiments of the disclosure provide flexible monitoring systems including circuits that can share a common architecture (e.g., hardware, software, firmware, etc.) and that can be configured to perform different designated functions (e.g., input, processing, output, system operation, etc.). By separating functions of the flexible monitoring system into different circuits, new implementations of the flexible monitoring system can be developed, in some cases rapidly, by arranging already created circuits in different combinations. This common component architecture can also reduce the amount of resources needed to manage multiple implementations of the flexible monitoring system, as each implementation can include components in common.

Embodiments of systems and corresponding methods for monitoring industrial machines are discussed herein. However, embodiments of the disclosure can be employed for monitoring other machines without limit.

An operating environment 100 containing an existing monitoring system is illustrated in FIG. 1. The operating environment 100 can include a target 102, at least one sensor 104, and a monitoring system 106 in communication with the sensor 104, an internal network 110 a, and an external network 110 b.

The target 102 can be any component of any machine. Examples of the target 102 can include gears, bearings, and shafts, amongst others. Examples of machines can include turbomachines, turbines (e.g., hydro, wind), generators, and reciprocating compressors.

The sensor 104 can be configured to sense an operating parameter of the target 102, to generate at least one sensor signal 104 s representing the measured operating parameter, and to transmit the sensor signal 104 s to the monitoring system 106 (e.g., via field wiring). As an example, the sensor 104 can include a probe, a transducer, and a signal conditioning circuit (not shown). The probe can interact with the target 102 for measurement of the operating parameter. The transducer can convert measurements of the operating parameter into an electrical signal (e.g., a voltage). The signal conditioning circuit can condition and/or amplify the electrical signal to generate the sensor signal 104 s (e.g., a voltage ranging between a minimum and maximum). Thus, in one aspect, the sensor signal 104 s can contain the direct or raw measurement made by the sensor transducer. The sensor signal 104 s can be an analog signal or a digital signal.

In another aspect, the sensor signals 104 s can also include an enhanced data set, in addition to the direct measurements of the operating parameter. The enhanced data set can contain a variety of measured variables that depend upon the type of operating parameter being measured. As an example, the target 102 can be a rotating component, such as a shaft, and radial vibration can be a variable measured by a sensor 104 in the form of a proximity sensor. Under these circumstances, the enhanced data set can include one or more of a gap voltage, a 1× filtered amplitude, a 2× filtered amplitude, a 1× filtered phase, a 2× filtered phase, Not 1× amplitude, and maximum shaft displacement (Smax). Gap voltage is the voltage output by the probe and represents the physical distance between the target 102 and a tip of the probe. 1× amplitude is the amplitude of vibrations having the same frequency as the shaft rotation, while 2× amplitude is the amplitude of vibrations having a frequency twice that of the shaft rotation. For instance, a rotation speed of 1480 revolutions per minute corresponds to a frequency of 24.66 cycles per second (Hz). Phase is the time delay between a vibration measured at a predetermined measurement location with respect to a reference location. Thus, 1× phase refers to phase of vibrations having the same frequency as the shaft rotation, while 2× phase refers to phase of vibrations having a frequency twice that of the shaft rotation. Not 1× amplitude refers to all amplitudes except for the 1× amplitude. In other embodiments, the enhanced data set can include metadata regarding one or more components of the sensor 104, such as the transducer. Examples of metadata can include one or more of a serial number, revision number, operating temperature, and state of health.

The number and type of sensor 104 can be dictated by the operating parameter(s) that are intended to be measured. In one aspect, the sensor 104 can take the form of one or more proximity probes for measurement of vibration, position, speed, direction of motion, and eccentricity. In another aspect, the sensor 104 can take the form of one or more accelerometers for measurement of seismic vibration and acceleration. In a further aspect, the sensor 104 can take the form of one or more temperature probes or pressure probes for measurement of temperature and pressure, respectively. It can be understood that the sensor types and corresponding operating parameters listed above are not exhaustive and embodiments of the sensor 104 can include any sensor or combination of sensors suitable for measurement of operating parameters of interest.

In use, the monitoring system 106 can be configured to process the received sensor signals 104 s and output monitoring signals 106 s, 108 s. As an example, the monitoring system 106 can be configured to determine a value characterizing an operating parameter measurement. The monitoring system 106 can also compare this determined value, and/or any measured variables of the enhanced data set, to one or more corresponding predetermined alarm conditions in real-time and determine an alarm status (e.g., OK, not OK, alert, danger, etc.). For instance, when the target 102 is a rotating shaft and the measured operating parameter is radial vibration of the shaft, the sensor signal 104 s can include measurements of displacement of the shaft as a function of time. From the sensor signal 104 s, the monitoring system 106 can determine the value of vibration amplitude from the peak-to-peak displacement.

The monitoring system 106 can also be configured to output monitoring signals 106 s, 108 s to the internal network 110 a and/or the external network 110 b. The output monitoring signals 106 s, 108 s can include one or more of the measured variables of the enhanced data set, the determined values, and the determined status. Alarm statuses, such as alert and danger, can be annunciated via physical relays on the monitoring system 106 or to the external systems 110 by the monitoring signals 106 s, 108 s. In another aspect, the monitoring system 106 can additionally or alternatively store the sensor signals 104 s for later processing.

The internal network 110 a can be a plant network that is in communication with a machine control system 112. The machine control system 112 can be configured to provide commands to a machine operative to control one or more operating parameters of the target 102. The internal network 110 a can also be in communication with other systems, such as computing devices executing configuration software (not shown), human-machine interfaces (HMIs) 114 and/or a customer historian 116. The configuration software can be used to provide configuration information, such as the pre-determined alarm conditions, to the monitoring system 106. The HMI 114 can be one or more computing devices in communication with user interface devices (e.g., displays) allowing an operator of the machine to review measured operating parameters and/or provide instructions to the machine control system 112.

So configured, the monitoring system 106 can facilitate protection of a machine containing the target 102. As an example, in response to annunciation of an alarm status, the machine control system 112 can be utilized to control operation of the target 102 (e.g., automatically according to programmed logic or manually using the HMI 114) to cause the measured operating parameters to change and move out of the alarm status. Under extreme circumstances, the machine control system 112 can be employed to shut down operation of the machine to protect the target 102 from damage and/or workers from injury. The historian 116 can store any of the data contained within the monitoring signals 106 s.

The external network 110 b can be a business network that is in communication with a diagnostic system 120. The diagnostic system 120 can analyze any of the data contained within the monitoring signals 108 s received from the monitoring system 106 to diagnose improper operation of the target 102 and/or predict improper operation of the target 102 before it occurs. Thus, by providing monitoring signals 108 s to the external network 110 b, the monitoring system 106 can facilitate condition monitoring of the target 102.

The monitoring system 106 is illustrated in greater detail in FIG. 1B. As shown, the monitoring system 106 includes a backplane 150 that can be configured to allow communication between different components coupled thereto. The components can include a measurement processing circuit 152 a, a relay output circuit 154 a, a measurement output circuit 156 a, a configuration and diagnostic circuit 160 a, and corresponding interface circuits 152 b, 154 b, 156 b, 160 b. The interface circuits 152 b, 154 b, 156 b, 160 b can provide hardware interfaces for communication to and from their respective circuits 152 a, 154 a, 156 a, 160 a. The individual circuits 152 a, 154 a, 156 a, 160 a can communicate selected information on the backplane 150 using protocols running on busses formed from passive traces extending across the backplane 150.

In one aspect, the measurement processing circuit 152 a can be coupled to an interface circuit 152 b such that sensor signals 104 s received by the interface circuit 152 b are transmitted directly to the measurement processing circuit 152 a. That is, the sensor signals 104 s are not transmitted to the backplane 150. The sensor signals 104 s can be accessed by an operator through an output port 162. Multiple measurement processing circuits 152 a and interface circuit 152 b can be present, on a one-to-one basis, for receipt of the sensor signals 104 s. As discussed above, the measurement processing circuit 152 a can be configured to determine one or more values for the operating parameter measurements contained within the received sensor signal 104 s. The measurement processing circuit 152 a can also compare determined values, and/or measured variables of the enhanced data, to pre-determined alarm conditions in real-time and determine a status for the target 102. The measurement processing circuit 152 a can further output signals representing the measured variables of the enhanced data, the determined values, and the determined statuses to the backplane 150.

The measurement processing circuit 152 a can also format process variables (e.g., determined values, measured variables of the enhanced data set, annunciated alarms, etc.) for output to the machine control system 112. As an example, the format can be a current that ranges between about 4 mA to about 20 mA (also referred to as 4-20) and is proportional to the determined values and/or measured variable as compared to a corresponding scale. The machine control system 112 can utilize the process variables for process control of the target 102.

The statuses determined by the measurement processing circuits 152 a can be retrieved by the relay processing circuit 154 a from the backplane 150. The relay processing circuit 154 a can include relays that are programmed to actuate based upon received alarm statuses to annunciate an alarm. In one example, relays can actuate based upon a single status. In another example, relays can actuate based upon Boolean expressions (e.g., AND or voting) that combine two or more statuses. The relay processing circuit 154 a can also output signals representing annunciated alarms directly to the machine control system 112 for process control of the target 102. As an example, the machine control system 112 can shut down operation of the target 102 upon receipt of an alarm annunciation. Annunciated alarms can also be used to provide indications and/or to drive into digital input of the machine control system 112, the HMI 114, or historian 116.

The measurement output circuit 156 a can retrieve data such as determined values, measured variables of the enhanced data, determined statuses, and annunciated alarms from the backplane 150 for transmission to the internal network 110 a. Upon receipt, the retrieved data can be stored by the historian 116 and/or reviewed by an operator using the HMI 114.

The configuration and diagnostic circuit 160 a can receive first configuration commands from the internal network 110 a and transmit the first configuration commands to the backplane 150 for use by the circuits 152 a, 154 a, 156 a, 160 a. The first configuration commands can provide one or more set points for use by the measurement processing circuit 152 a in determining statuses. The first configuration commands can also provide logic instructions and identify statuses to be used by the relay output circuit 154 a for alarm annunciation. The first configuration commands can further identify data such as determined values, measured variables of the enhanced data, determined statuses, and/or annunciated alarms to be retrieved from the backplane 150 by the measurement output circuit 156 a and transmitted to the internal network 110 a.

The configuration and diagnostic circuit 160 a can also receive second configuration commands from the internal network 110 a. The second configuration commands can identify data such as determined values, measured variables of the enhanced data, determined statuses, and annunciated alarms to be retrieved from the backplane 150 and transmitted to the external network 110 b for use by the diagnostic system 120.

While capable of facilitating protection monitoring and condition monitoring of the target 102, in some instances, the architecture of monitoring systems such as monitoring system 106 can lack flexibility. In one aspect, placement of the configuration and diagnostic circuit 160 a in communication with both the internal and external networks 110 a, 110 b can cause delays when updating the second configuration commands. When diagnosing machine problems, it can be desirable to change the data received by the diagnostic system 120. However, transmissions to or from components in communication with the internal network 110 a can be strictly regulated in order to protect the machine control system 112 from unauthorized access. This regulation can include permitting the configuration and diagnostic circuit 160 a to transmit data to the external network 110 b for condition monitoring but prohibiting transmission of changes to the second commands from the external network 110 b to the configuration and diagnostic circuit 160 a. Instead, an authorized operator of the machine control system 112 can be required to approve any changes to the second configuration commands and transmit the updated second conditioning commands from the internal network 110 a to the configuration and diagnostic circuit 160 a.

In another aspect, directly coupling the interface circuit 152 b receiving the sensor signals 104 s to the measurement processing circuit 152 a can limit access of the sensor signal 104 s to only the measurement processing circuit 152 a. As a result, the other circuits 154 a, 156 a, 160 a of the monitoring system 106, as well as the diagnostic system 120, cannot utilize the raw operating parameter measurements transmitted by the sensor signal 104 s. Furthermore, should a second measurement processing circuit (not shown) be added to the monitoring system for receipt of additional sensor signals from another sensor, each measurement processing circuit could utilize the operating parameter measurements it receives but not operating parameters received by the other.

In a further aspect, process variables output by the measurement processing circuit 152 a to the machine control system 112 can be limited. In general, for each sensor signal 104 s received by the measurement processing circuit 152 a, there can be a variety of possible process variables (e.g., determined values and/or measured variables of the enhanced data set). As an example, there can be 8 possible process variables determined by the measurement processing circuit 152 a from a sensor signal 104 s measuring radial vibration (vibration amplitude, gap voltage, 1× filtered amplitude, 2× filtered amplitude, 1× filtered phase, 2× filtered phase, Not 1× amplitude, and Smax. However, the measurement processing circuit 152 a can possess the ability to output a single process variable for each sensor 104 from which it receives sensor signals 104 s.

One or more of these limitations can be addressed by embodiments of a flexible monitoring system of the present disclosure. FIG. 2A illustrates an exemplary embodiment of an operating environment 200 including a flexible monitoring system 202. The operating environment 200 can be similar to the operating environment 100, except that the monitoring system 106 is replaced with the flexible monitoring system 202. The flexible monitoring system 202 can include a base 204 containing a backplane 206, and one or more circuits 210. The backplane 206 can be configured to communicatively couple with two or more circuits 210 and receive data from at least one circuit 210 coupled thereto. As discussed herein, data transmitted to the backplane 206 can be referred to as monitoring data. In one aspect, monitoring data can include information contained within the sensor signals 104 s, such as measured operating parameters of the target 102 and measured variables of the enhanced data set. Monitoring data can also include any values, statuses, and/or annunciated alarms that are determined based upon the measured operating parameters of the target 102 and/or measured variables of the enhanced data set. Circuits 210 coupled to the backplane 206 can retrieve monitoring data from the backplane 206. In certain embodiments, the backplane 206 can be passive. A passive backplane can contain substantially no or no logical circuitry that performs computing functions. Desired arbitration logic can be placed on daughter cards (e.g., one or more of the circuits 210) plugged into or otherwise communicatively coupled to the passive backplane.

In contrast to the circuits 152 a, 154 a, 156 a, 160 a of the monitoring system 106, the circuits 210 can be designed with a common architecture that is programmable to perform different predetermined functions of the flexible monitoring system 202. Sensor signals 104 s received by one or more of the circuits 210 can be transmitted to the backplane 206 and monitoring data represented by the sensor signals 104 s can be accessed by any circuit 210. Furthermore, the flexible monitoring system 202 can communicatively couple multiple bases in a manner that forms a common backplane 206′ from the individual backplanes 206 of each base 204 (e.g., a logical backplane). Thus, circuits 210 can retrieve monitoring data from any backplane 206 forming the common backplane 206′, rather than just from the backplane 206 to which they are physically coupled.

In certain embodiments, the circuits 210 of the flexible monitoring system 202 can be configured to provide at least functionality similar to that of circuits 152 a, 154 a, 156 a, 160 a of the monitoring system 106. Exemplary embodiments of circuits 210 are illustrated in FIGS. 2A-3 and discussed in detail below. As an example, circuits 210 can include input circuits 210 i, processing circuits 210 p, output circuits 210 o, and infrastructure circuits 210 n. It can be understood, however, that the circuits 210 can be programmed to perform other functions. Further discussion of the circuits 210 can also be found in U.S. patent application Ser. No. 15/947,716 entitled “Gated Asynchronous Multipoint Network Interface Monitoring System,” the entirety of which is incorporated by reference. Accordingly, the flexible monitoring system 202 can be configured to receive sensor signals 104 s and output monitoring signals 206 s, 208 s to the internal and external networks 110 a, 110 b, respectively. As discussed in detail below, embodiments of the flexible monitoring system 202 can receive command signals 209 s, 211 s from the internal and external networks 110 a, 110 b, respectively, without compromising security of the machine control system 112. As a result, the flexible monitoring system 202 can be a suitable replacement for existing deployments of monitoring systems 106 while providing improved flexibility and functionality.

With this architecture, the circuits 210 can be combined in various ways on one or more backplanes 206 to form different implementations of the flexible monitoring system 202. The number of bases 204, input circuits 210 i, processing circuits 210 p, output circuits 210 o, and infrastructure circuits 210 n included in a given implementation of the flexible monitoring system 202 can also be varied independently of one another. In some implementations, the flexible monitoring system 202 can be in the form of a single base 204 including circuits 210 configured to provide signal input, signal output, protection monitoring, condition monitoring, and combinations thereof. In other implementations, the flexible monitoring system 202 can be in the form of at least two bases 204 and circuits 210 configured to perform any combination of signal input, signal output, protection monitoring, and condition monitoring can be distributed between the at least two bases 204. In this manner, the input, processing, and output capabilities of the flexible monitoring system 202, as well as the physical location of different circuits 210 of the flexible monitoring system 202, can be tailored to specific monitoring applications.

Furthermore, implementations of the flexible monitoring system 202 can be modified after initially deployed to modify the circuits 210 coupled to a given base 204 in the event that the intended monitoring application changes. Given their common architecture, circuits 210 can be easily added to a base 204 having capacity to couple to a new circuit 210. Alternatively, one or more new bases 204 can be communicative coupled to an existing base 204, allowing one or more new circuits 210 to be couple to respective backplane(s) 206 of the new base(s) 204 and expanding the monitoring capabilities of the flexible monitoring system 202. In some instances, circuits 210 removed from one base 204 of the flexible monitoring system 202 can be stored in reserve as spares or redeployed to another base 204 of the same or a different implementations of the flexible monitoring system 202, which may be beneficial.

In certain embodiments, input circuits 210 i can be configured to receive sensor signals 104 s, perform signal conditioning on the sensor signals 104 s, and output the conditioned sensor signals 104 s to the backplane 206. In contrast to the monitoring system 106 of FIGS. 1A-1B, the input circuits 210 i can be decoupled from processing circuits 210 p, allowing the number of input circuits 210 i of the flexible monitoring system 202 to be varied independently of the number of processing circuits 210 p.

The sensor signals 104 s can be received from a variety of different types of sensor 104. Examples of sensor types can include, but are not limited to, vibration sensors, temperature sensors (e.g., resistance temperature detectors or RTD), position sensors, and pressure sensors.

Embodiments of the flexible monitoring system 202 can include one or more input circuits 210 i. As shown in the FIG. 2A, the flexible monitoring system 202 includes two input circuits 210 i. Each of the input circuits 210 i can be in communication with a respective sensor 104 for receipt of a corresponding sensor signal 104 s. As an example, one sensor signal 104 s can represent first monitoring data including measurements of a first operating parameter of a first machine component (e.g., acquired by a first sensor). The other sensor signal 104 s can represent second monitoring data including measurements of a second operating parameter of a second machine component (e.g., acquired by a second sensor, different from the first sensor). In certain embodiments, the first and second machine components can be the same (e.g., the target 102). In other embodiments, the first and second machine components can be different (e.g., the target 102 and a different target [not shown]). Similarly, in some embodiments, the first and second operating parameters can be the same operating parameter. In one aspect, this configuration can provide redundancy in case of failure of one of the sensors 104. In another aspect, this configuration can be utilized where a desired measurement (e.g., shaft rotation speed) is derived from two sensor measurements coordinated in time (phase). In additional embodiments, the first and second operating parameters can be different. While two input circuits 210 i have been illustrated and discussed, other embodiments of the monitoring system can include greater or fewer input circuits.

Different types of sensors 104 can generate sensor signals 104 s in different formats, and input circuits 210 i can be programmed to perform signal conditioning appropriate to the different sensor signals 104 s before transmitting conditioned sensor signals to the backplane 206. As an example, a sensor signal 104 s received from a position sensor can be received by a position input circuit 250. A sensor signal 104 s received from a vibration sensor can be received by a vibration input circuit 252. A sensor signal 104 s received from a temperature sensor can be received by a temperature input circuit 254. A sensor signal 104 s received from a pressure sensor can be received by a pressure input circuit 256.

In other embodiments, the input circuit 210 i can be in the form of a discrete contact circuit 260. The discrete contact circuit 260 can include a pair of contacts that can be closed by an external switch or relay. The pair of contacts can be closed by the machine control system 112 or by an operator of the machine control system 112 closing a switch. The discrete contact circuit 260 can be used to change the behavior of the flexible monitoring system 202. Examples of behavior changes can include, but are not limited to, a different mode of machine operation, causing the flexible monitoring system 202 to inhibit alarm determination, and resetting alarm states.

While the monitoring system 106 can include a discrete contact, it can lack specificity. As an example, changes effected by closing a discrete contact in the measurement system 106 can be effected upon all alarms generated by the measurement system 106. In contrast, because the discrete contact circuit 260 of the flexible monitoring system 202 can be separate from the protection processing circuit 264, the discrete contact circuit 260 can be configured to effect only selected alarm determinations and/or reset alarm states, or effect all alarms.

In further embodiments, the input circuit 210 i can be in the form of a digital data stream input circuit 262. As an example, the digital data stream input circuit 262 can be configured to receive digital data streams from the sensor 104, the machine control system 112, and/or a trusted third-party system, as opposed to an analog data stream (e.g., from sensor 104).

Processing circuits 210 p can be configured to retrieve any data from the backplane 206, analyze the retrieved operating parameters, and output the results of such analysis. In certain embodiments, the processing circuits 210 p can be configured to perform protection functions and can be referred to as protection processing circuits 264 herein. In other embodiments, the processing circuits 210 p can be configured to retrieve selected data from the backplane 206 and transmit the retrieved information to the diagnostic system 120 for performing diagnostic and/or predictive functions (e.g., condition monitoring) and can be referred to as condition processing circuits 266 herein.

The number of processing circuits 210 p and input circuits 210 i included in a given implementation of the flexible monitoring system 202 can be varied independently of the one another. In certain embodiments, processing circuits 210 p can be added to the backplane 206 or removed from the backplane to tailor the amount of computing resources available for protection monitoring and/or condition monitoring. In other embodiments, a given processing circuit 210 p can be replaced by another processing circuit 210 p having greater or less computing power.

Any of these scenarios can be beneficial under certain circumstances, providing computational flexibility to the flexible monitoring system 202 that can be tailored to a given application and/or modified as needed. In one instance, machines having relatively low importance can have higher cost pressures and lower processing requirements. In this circumstance, an implementation of the flexible monitoring system 202 can include processing circuits 210 p having processing resources tailored for cost. In another instance, a particular monitoring application can require high processing requirements (e.g., for determining values characterizing the measured parameters, for output of monitoring data, etc.). In this circumstance, an implementation of the flexible monitoring system 202 can include processing circuits 210 p having processing resources tailored for processing resources. Thus, the architecture of the flexible monitoring system 202 can allow adaptation for different use cases depending upon the priorities of the intended monitoring application.

The protection processing circuits 264 and the condition processing circuits 266 are discussed below with reference to different functionalities. However, protection processing circuits 264 can be programmed to perform any function of the condition processing circuits 266. Condition processing circuits 266 can be programmed to perform functions of the protection processing circuits 264, except for transmitting data to the backplane 206 and providing local storage. The ability to inhibit the condition processing circuit 266 from transmitting data to the backplane 206 can inhibit unauthorized intrusion and facilitate protection of the internal network 110 a and machine control system 112.

Protection processing circuits 264 can be configured to retrieve selected monitoring data from the backplane 206 in response to receipt of a protection command. As an example, one or more protection commands can be transmitted to protection processing circuits 264 in the form of protection command signal 209 s received from the internal network 110 a (e.g., from an operator of the machine control system 112). The selected monitoring data can include at least a portion of the monitoring data transmitted to the backplane 206. The monitoring data transmitted to the backplane can be received from an input circuit 210 i or another protection processing circuit 264. The protection processing circuits 264 can also be configured to determine a value characterizing the selected monitoring data and transmit the determined value to the backplane 206 as additional monitoring data.

The protection processing circuit 264 can be configured to determine a status for the selected monitoring data based upon a comparison of the determined value, another determined value retrieved from the backplane 206 (e.g., from another protection processing circuit 264), and combinations thereof, with one or more predetermined set points. Predetermined set points can correspond to respective alarm conditions (e.g., an Alert condition, a Danger condition, etc.). Continuing the example above, where the determined value is an amplitude of a radial vibration, the one or more set points can include an Alert set point, a Danger set point that is greater than the Alert set point, and combinations thereof. In certain embodiments, a single set point can be employed. Assuming the use of Alert and Danger set points, if the radial vibration amplitude value is less than the Alert set point, the status of the radial vibration amplitude can be determined as “OK.” If the radial vibration amplitude value is greater than or equal to the Alert set point, the status of the radial vibration amplitude can be determined as “Alert.” If the radial vibration amplitude value is greater than the Danger set point, the status of the operating parameter can be determined as “Danger.” After the status of the selected monitoring data is determined in this manner, the protection processing circuit 264 can transmit the determined status to the backplane 206. The condition processing circuit 266 can be configured to retrieve selected monitoring data from the backplane 206 and to provide the retrieved monitoring data to the external network 110 b for use by diagnostic system 120. In certain embodiments, the selected monitoring data can be retrieved by the condition processing circuit 266 in response to receipt of a conditioning command. As an example, one or more conditioning commands can be transmitted to condition processing circuits 266 in the form of conditioning command signals 211 s can be received from the external network 110 b. (e.g., from an operator of the diagnostic system 120). In turn, the diagnostic system 120 can utilize the retrieved monitoring data to determine the cause of statuses and/or alarm conditions. Alternatively or additionally, the diagnostic system 120 can also employ the retrieved monitoring data to predict the development of statuses and/or alarm conditions before they arise. In further embodiments, the diagnostic system 120 can store the retrieved monitoring data for subsequent analysis. In additional embodiments, the diagnostic system 120 can transmit the retrieved monitoring data to another computing device for analysis.

In further embodiments, the condition processing circuit 266 can retrieve selected monitoring data from the backplane 206 based upon detection of a pre-determined status. As an example, the condition processing circuit 266 can retrieve and review statuses generated by the protection processing circuit 264 to identify a status matching the pre-determined status. The identified status can also include a status time characterizing the time when the status was determined. Upon identification of a match, the condition processing circuit 266 can retrieve selected monitoring data including operating parameter measurements corresponding to the pre-determined status for time durations before and/or after the status time. In this manner, the diagnostic system 120 can be provided with operating parameter information relevant to determining the cause of the status. The pre-determined statuses and selected monitoring data can be contained within the one or more conditioning commands.

The number of condition processing circuits 266 present in the flexible monitoring system 202 can be varied independently of the number of input circuits 210 i. In certain embodiments, condition processing circuit 266 can be added to increase the ability of the flexible monitoring system 202 to output monitoring data. As an example, when two or more condition processing circuits 266 are present in the flexible monitoring system 202, each can tasked with output of different measured operating parameters. In another example, two or more condition processing circuits 266 can output the same measured operating parameters in order to provide redundancy. Each can be beneficial under certain circumstances, providing computational flexibility to the flexible monitoring system 202. In a further example, condition processing circuits 266 can be added to implement custom analytics without interfering with standard operation (e.g., when beta-testing a new analytic).

Output circuits 210 o can be configured to obtain any monitoring data contained on the backplane 206 in response to receipt of output commands (e.g., contained in the one or more protection command signal 209 s received from the internal network 110 a). The output circuits 210 o can further output the retrieved monitoring data to the internal network 110 a in the form of monitoring signals 206 s. Examples of monitoring data retrieved by output circuits 210 o can include, but are not limited to, operating parameter measurements, the determined values, variables of the enhanced data set, statuses, and alarms.

In one aspect, output circuits 210 o can be in the form of proportional output circuits 270. The proportional output circuits 270 can be configured to output monitoring signals 206 s in the form of process control signals 300 s. The process control signals 300 s can be proportional to process variables, such as direct measurement values or variables of the enhanced data set, as compared to a predetermined scale. As an example, a current output can be a 4-20 mA output. The process control signals 300 s can be provided to the machine control system 112, either directly or via the internal network 110 a, to facilitate control of operating parameters of the target 102. The process variables included in the process control signals 300 can be specified by the protection command signal 209 s.

In further embodiments, output circuits 210 o can be in the form of one or more relay circuits 272 configured to retrieve selected status data from the backplane 206 and to actuate based upon received alarm statuses to annunciate an alarm. Annunciated alarms can be output in the form of alarm signals 302 s. In one example, relays can actuate based upon a single status. In another example, relays can actuate based upon predetermined Boolean expressions (e.g., AND or OR voting) that combine two or more statuses. The alarm signals 302 s can be provided to the machine control system 112 via the internal network 110 a, or directly to the machine control system 112, to facilitate control of operating parameters of the target 102. As an example, the machine control system 112 can shut down operation of the target 102 in response to receipt of an alarm signal 302 s. The selected status data and the logic employed for actuation of a relay can be specified by the protection command signal 209 s

In other embodiments, output circuits 210 o can be in the form of at least one communication interface circuits 274. The communication interface circuit 274 can be configured to retrieve selected monitoring data from the backplane 206 in response to receipt of the protection command signal 209 s. The selected monitoring data can include one or more of the measured operating parameters, the measured variables of the enhanced data set, determined statuses, and determined alarms. The retrieved data can be transmitted to the internal network 110 a in one or more return signals 306 s for use by machine control system 212 (e.g., for process control), the HMI 114 (e.g., display to an operator) and/or stored by the historian 116.

Infrastructure circuits 210 n can be configured to perform functionality required for the flexible monitoring system 202 to operate. In one aspect, infrastructure circuits 210 n can take the form of a system interface circuit 276. The system interface circuit 276 can function as an access point for transmission of protection command signals 209 s from the internal network 110 a to the monitoring system 220, facilitating configuration of the circuits involved in protection monitoring (e.g., protection processing circuit 264, output circuits 210 i). The protection command signals 209 s can include one or more signals including any of the following in any combination: identification of selected monitoring data for each of the protection processing circuit 264 and output circuits 210 i to retrieve and/or output, alarm set points for the protection processing circuit 264, and logic for annunciation of relays by relay output circuits 272.

It can be appreciated that, in contrast to the monitoring system 106, embodiments of the flexible monitoring system 202 can separate the circuits 210 that configure protection monitoring functions (e.g., the system interface circuit 276) and condition monitoring functionality (e.g., the condition processing circuit 266). As a result, protection monitoring configuration can be performed entirely on the internal network 110 a while condition monitoring configuration can be performed entirely on the external network 110 b. That is, the internal network 110 a is not communicatively coupled to the external network 110 b. As a result, conditioning command signals 211 s can be provided to the condition processing circuit 266 without the need to obtain approval from an authorized operator of the machine control system 112.

In appreciation of cybersecurity risks inherent in allowing the condition processing circuit 266 to communicate with the external network 110 b and the backplane 206, the condition processing circuit 266 can be limited to unidirectional communication with the backplane 206 for data retrieval only. Such unidirectional communication can be established by any combination of hardware (e.g., data diodes), firmware, and/or software. In certain embodiments, this unidirectional communication is provided at least through hardware. As a result, the flexible monitoring system 202 can be kept secure from malicious actors while facilitating rapid configuration of the condition processing circuit 266.

In another aspect, infrastructure circuits 210 n can take the form of power input circuits 280. Power input circuits 280 can provide the ability to connect one or more power sources to the flexible monitoring system 202.

In a further aspect, infrastructure circuits 210 n can take the form of bridge circuits 282. The bridge circuits 282 can provide the ability to connect the backplanes 206 of two or more bases 204 together and to form the common backplane 206′ for communication therebetween.

So configured, embodiments of the circuits 210 can be arranged in any combination distributed amongst one or more bases 204 to form implementations of the flexible monitoring system having desired monitoring capabilities (e.g., input, processing, output, etc.). Exemplary embodiments of flexible monitoring systems 202 constructed from different groupings of circuits 210 and bases 204 to provide different monitoring functions are illustrated in FIGS. 4A-4C, respectively.

FIG. 4A illustrates the flexible monitoring system 202 in the form of flexible monitoring system 400 that can be considered as relatively large and it can be configured to perform both protection monitoring and condition monitoring for a variety of different sensor types. As shown, the flexible monitoring system 400 includes input circuits 210 i such as vibration input circuits 252 (VI), temperature input circuits 254 (TI), a discrete contact circuit 260 (DC). The flexible monitoring system 400 also include processing circuits 210 p such as protection processing circuits 264 configured to provide protection monitoring functionality (PM) and condition processing circuits 266 configured to provide condition monitoring functionality (CM). The flexible monitoring system 400 can further include output circuits 210 o, such as relay output circuits 272 (RO), proportional output circuits 270 (4-20), and communication interface circuits 274 (CI). The flexible monitoring system 400 can additionally include infrastructure circuits 210 n, such as power input circuits 280 (PI) and system interface circuits 276 (SI).

FIG. 4B illustrates the flexible monitoring system 202 in the form of a flexible monitoring system 402 that can be smaller than the flexible monitoring system 400 (e.g., a “medium” system) and it can be configured to perform protection monitoring for a single type of sensor 104. As shown, the flexible monitoring system 402 includes input circuits 210 i such as vibration input circuits 252 (VI). The flexible monitoring system 402 can also have processing circuits 210 p including a protection processing circuits 264 (PM). The flexible monitoring system 402 can also include output circuits 210 o such as relay output circuits 272 (RO) and proportional output circuits 270 providing 4 mA-20 mA outputs (4-20). The flexible monitoring system 402 can additionally include infrastructure circuits 210 n, such as power input circuits 280 (PI) and bridge circuits 282 (BR).

FIG. 4C illustrates the flexible monitoring system 202 in the form of flexible monitoring system 404 that can be smaller than both of the flexible monitoring systems 400 and 402 (e.g., a “small” system) and it can be configured to perform protection monitoring for a single type of sensor 104. As shown in FIG. 4C, the flexible monitoring system 404 includes a single input circuit 210 i, such as a vibration input circuit 252 (VI). The flexible monitoring system 404 can also have a processing circuit 210 p including a protection processing circuit 264 (PM). The flexible monitoring system 404 can also include output circuits 210 o such as relay output circuits 272 (RO). The flexible monitoring system 404 can additionally include infrastructure circuits 210 n, such as power input circuits 280 (PI) and bridge circuits 282 (BR).

In further embodiments, the flexible monitoring system 202 can be composed of multiple bases 204 that are communicatively coupled through bridge circuits 282. In this manner, the common backplane 206′ can extend across all of the bridge-coupled bases 204, where all information from the backplane 206 of each base 204 can be transmitted to the backplanes 206 of any other bases 204.

An exemplary embodiment the flexible monitoring system 202 in the form of flexible monitoring system 500 is illustrated in FIG. 5. As shown, the flexible monitoring system 500 includes three bases, 502, 504, and 506 communicatively coupled to one another at their respective bridge circuits 282 (BR) using communication links 510. The communication links 510 can be any communication connection including, but not limited to, electrical cables, fiber optic cables, and wireless communication. The base 502 can contain discrete contact circuits 260, condition processing circuits 266 (CM), relay output circuits 272 (RO), and communication interface circuit 274 (CI). The base 504 can contain vibration input circuits 252 (VI), protection processing circuits 264 (PM), relay output circuits 272 (RO), and proportional output circuits 270 providing 4 mA-20 mA outputs (4-20). The base 506 can contain vibration input circuits 252 (VI) and relay output circuits 272 (RO). Each of the bases 502, 504, 506 can also include respective bridge circuits 282 (BR) and power input circuits 280 (PI). Protection command signals 209 s can be provided to each of the bases 502, 504, 506, via the common backplane 206′, using the system interface circuit 276 (SI) mounted to the base 502.

Another exemplary embodiment of the flexible monitoring system 202 in the form of flexible monitoring system 600 is illustrated in FIG. 6. As shown, the flexible monitoring system 600 includes two bases, 602 and 604 communicatively coupled to one another at their respective bridge circuits 282 (BR) using communication links 606, similar to communication links 510. The base 602 can contain all processing circuits 210 p, while the base 604 can contain all or substantially all of the input circuits 210 i and the output circuits 210 o. The base 604 can be located remotely from the base 602, such as in a marshalling cabinet, while the base 602 can remain close to a control room for ease of access.

In order to improve the efficiency of embodiments of the flexible monitoring system 202, circuits 210 can be segregated by function and shared between respective bases 204 over the bridge circuits 282 (BR). An exemplary embodiment of the flexible monitoring system 202 in the form of flexible monitoring system 700 is illustrated in FIG. 7. As shown, the flexible monitoring system 700 includes five bases, 702, 704 a, 704 b, 704 c, 704 d. The base 702 includes both protection processing circuits 264 (PM) and condition processing circuits 266 (CM). The bases 704 a-704 d are each the same and include temperature input circuits 254 (TI) and vibration input circuits 252 (VI). The bases 702 and 704 a-704 d are communicatively coupled to one another at their respective bridge circuits 282 (BR) by communication links 706, which can be the same as communication links 510. This configuration can allow the expensive common circuits (e.g., protection processing circuit 264, condition processing circuit 266, communication interface circuit 274, system interface circuit 276) to be housed in base 702 and placed close to a control room. Input circuits 210 i, such as temperature input circuits 254 (TI) and vibration input circuits 252 (VI)) can be housed in bases 704 a-704 d to be used for monitoring several small machines and positioned local to the monitored machine(s).

FIG. 8 is a flow diagram illustrating an exemplary embodiment of a method 800 for monitoring a machine. The method 800 is discussed in with reference to the flexible monitoring system 202. In certain aspects, embodiments of the method 800 can include greater or fewer operations than illustrated in FIG. 8 and the operations can be performed in a different order than illustrated in FIG. 8.

In operation 802, a first input circuit and a second input circuit can be communicatively coupled to a backplane of a base.

In operation 804, the first input circuit can transmit first monitoring data to the backplane. The first monitoring data can represent measurements of a first operating parameter of a first machine component. The first operating parameter can be acquired by a first sensor.

In operation 806, the second input circuit can transmit second monitoring data to the backplane. The second monitoring data can represent measurements of a second operating parameter of a second machine component. The second operating parameter can be acquired by a first sensor. In certain embodiments, the first and second machine components can be the same machine component. In other embodiments, the first and second machine components can be different machine components. The first and second operating parameters can be the same operating parameter or different operating parameters. In further embodiments, the first and second sensors can be different sensors.

In operation 810, a protection processing circuit can be coupled to the backplane.

In operation 812, the protection processing circuit can retrieve first selected monitoring data from the backplane in response to receipt of a first protection command. The first selected monitoring data can include at least a portion of at least one of the first and second monitoring data. In certain embodiments, the first protection command can be transmitted to the backplane by a system interface circuit coupled to the backplane. The first protection command can include information identifying the first selected monitoring data for retrieval by the protection processing circuit.

In operation 814, the protection processing circuit can determine a value characterizing the first selected monitoring data.

In operation 816, the protection processing circuit can transmit the determined value to the backplane.

In additional embodiments, the first protection command can include a set point corresponding to an alarm condition (e.g., Alert, Danger, etc.) for the first monitoring data. The protection processing system can be configured to determine a status for the first monitoring data based upon the set point. As an example, the magnitude of the determined value can be compared to the set point to determine the status. Once determined, the protection processing circuit can transmit the status to the backplane.

In further embodiments, an output circuit can be communicatively coupled to the backplane. The output circuit can retrieve second monitoring data from the backplane in response to receipt of a second protection command. The retrieved second monitoring data can be output, by the output circuit, to an internal network in communication with a machine control system operative to control the first and second operating parameters of the first and second machine components. The second monitoring data can include at least a portion of at least one of the first operating parameter measurements and the second operating parameter measurements.

In other embodiments, a condition processing circuit can be communicatively coupled to the backplane. The condition processing circuit can be configured to retrieve third selected monitoring data from the backplane in response to receipt of a conditioning command from an external network, different from the internal network. The condition processing circuit can also be configured to transmit the retrieved third selected monitoring data to the external network. The condition processing circuit can be prohibited from transmitting information to the backplane. The third selected monitoring data can include at least a portion of at least one of the first operating parameter measurements and the second operating parameter measurements.

In additional embodiments, the condition processing circuit can be configured to perform the following in response to receipt of the conditioning command. In one aspect, the condition processing circuit can retrieve a status for the first monitoring data at a status time from the backplane. In another aspect, the condition processing circuit can determine that the retrieved status matches a predetermined status. The predetermined status can be provided by the conditioning command. The condition processing circuit can further retrieve a portion of at least one of the first and second operating parameter measurements occurring adjacent in time to the status time. In certain embodiments, the retrieved portion of at least one of the first and second operating parameter measurements can occur immediately prior or immediately after the status time.

Exemplary technical effects of the methods, systems, and devices described herein include, by way of non-limiting example, circuits that possess a common architecture. The common architecture can reduce the number of components that are managed within a monitoring system and allow the use of common spares across multiple monitoring systems. The common architecture of the circuits can also allow them to operate similarly, providing a reduction in problems due to misunderstanding of differences in behavior of different monitoring systems. The circuits can be separated into different circuits that perform predetermined functions (e.g., input, processing, output, system). The common architecture and separation of functions can further allow the circuits to be combined in any combination to form new implementations of the monitoring systems having desired machine monitoring capabilities.

Certain exemplary embodiments have been described to provide an overall understanding of the principles of the structure, function, manufacture, and use of the systems, devices, and methods disclosed herein. One or more examples of these embodiments have been illustrated in the accompanying drawings. Those skilled in the art will understand that the systems, devices, and methods specifically described herein and illustrated in the accompanying drawings are non-limiting exemplary embodiments and that the scope of the present invention is defined solely by the claims. The features illustrated or described in connection with one exemplary embodiment may be combined with the features of other embodiments. Such modifications and variations are intended to be included within the scope of the present invention. Further, in the present disclosure, like-named components of the embodiments generally have similar features, and thus within a particular embodiment each feature of each like-named component is not necessarily fully elaborated upon.

The subject matter described herein can be implemented in analog electronic circuitry, digital electronic circuitry, and/or in computer software, firmware, or hardware, including the structural means disclosed in this specification and structural equivalents thereof, or in combinations of them. The subject matter described herein can be implemented as one or more computer program products, such as one or more computer programs tangibly embodied in an information carrier (e.g., in a machine-readable storage device), or embodied in a propagated signal, for execution by, or to control the operation of, data processing apparatus (e.g., a programmable processor, a computer, or multiple computers). A computer program (also known as a program, software, software application, or code) can be written in any form of programming language, including compiled or interpreted languages, and it can be deployed in any form, including as a stand-alone program or as a module, component, subroutine, or other unit suitable for use in a computing environment. A computer program does not necessarily correspond to a file. A program can be stored in a portion of a file that holds other programs or data, in a single file dedicated to the program in question, or in multiple coordinated files (e.g., files that store one or more modules, sub-programs, or portions of code). A computer program can be deployed to be executed on one computer or on multiple computers at one site or distributed across multiple sites and interconnected by a communication network.

The processes and logic flows described in this specification, including the method steps of the subject matter described herein, can be performed by one or more programmable processors executing one or more computer programs to perform functions of the subject matter described herein by operating on input data and generating output. The processes and logic flows can also be performed by, and apparatus of the subject matter described herein can be implemented as, special purpose logic circuitry, e.g., an FPGA (field programmable gate array) or an ASIC (application-specific integrated circuit).

Processors suitable for the execution of a computer program include, by way of example, both general and special purpose microprocessors, and any one or more processor of any kind of digital computer. Generally, a processor will receive instructions and data from a read-only memory or a random access memory or both. The essential elements of a computer are a processor for executing instructions and one or more memory devices for storing instructions and data. Generally, a computer will also include, or be operatively coupled to receive data from or transfer data to, or both, one or more mass storage devices for storing data, e.g., magnetic, magneto-optical disks, or optical disks. Information carriers suitable for embodying computer program instructions and data include all forms of non-volatile memory, including by way of example semiconductor memory devices, (e.g., EPROM, EEPROM, and flash memory devices); magnetic disks, (e.g., internal hard disks or removable disks); magneto-optical disks; and optical disks (e.g., CD and DVD disks). The processor and the memory can be supplemented by, or incorporated in, special purpose logic circuitry.

To provide for interaction with a user, the subject matter described herein can be implemented on a computer having a display device, e.g., a CRT (cathode ray tube) or LCD (liquid crystal display) monitor, for displaying information to the user and a keyboard and a pointing device, (e.g., a mouse or a trackball), by which the user can provide input to the computer. Other kinds of devices can be used to provide for interaction with a user as well. For example, feedback provided to the user can be any form of sensory feedback, (e.g., visual feedback, auditory feedback, or tactile feedback), and input from the user can be received in any form, including acoustic, speech, or tactile input.

The techniques described herein can be implemented using one or more modules. As used herein, the term “module” refers to computing software, firmware, hardware, and/or various combinations thereof. At a minimum, however, modules are not to be interpreted as software that is not implemented on hardware, firmware, or recorded on a non-transitory processor readable recordable storage medium (i.e., modules are not software per se). Indeed “module” is to be interpreted to always include at least some physical, non-transitory hardware such as a part of a processor or computer. Two different modules can share the same physical hardware (e.g., two different modules can use the same processor and network interface). The modules described herein can be combined, integrated, separated, and/or duplicated to support various applications. Also, a function described herein as being performed at a particular module can be performed at one or more other modules and/or by one or more other devices instead of or in addition to the function performed at the particular module. Further, the modules can be implemented across multiple devices and/or other components local or remote to one another. Additionally, the modules can be moved from one device and added to another device, and/or can be included in both devices.

The subject matter described herein can be implemented in a computing system that includes a back-end component (e.g., a data server), a middleware component (e.g., an application server), or a front-end component (e.g., a client computer having a graphical user interface or a web browser through which a user can interact with an implementation of the subject matter described herein), or any combination of such back-end, middleware, and front-end components. The components of the system can be interconnected by any form or medium of digital data communication, e.g., a communication network. Examples of communication networks include a local area network (“LAN”) and a wide area network (“WAN”), e.g., the Internet.

Approximating language, as used herein throughout the specification and claims, may be applied to modify any quantitative representation that could permissibly vary without resulting in a change in the basic function to which it is related. Accordingly, a value modified by a term or terms, such as “about,” “approximately,” and “substantially,” are not to be limited to the precise value specified. In at least some instances, the approximating language may correspond to the precision of an instrument for measuring the value. Here and throughout the specification and claims, range limitations may be combined and/or interchanged, such ranges are identified and include all the sub-ranges contained therein unless context or language indicates otherwise.

One skilled in the art will appreciate further features and advantages of the invention based on the above-described embodiments. Accordingly, the present application is not to be limited by what has been particularly shown and described, except as indicated by the appended claims. All publications and references cited herein are expressly incorporated by reference in their entirety. 

1. A system, comprising: a backplane configured to couple to a plurality of circuits and to receive monitoring data from at least one circuit coupled to the backplane; a first input circuit coupled to the backplane and configured to receive a first sensor signal from a first sensor, the first sensor signal representing first monitoring data including measurements of a first operating parameter of a first machine component, and to transmit the first monitoring data to the backplane; a second input circuit coupled to the backplane and configured to receive a second sensor signal from a second sensor, different from the first sensor, the second sensor signal representing second monitoring data including measurements of a second operating parameter of a second machine component, and to transmit the second monitoring data to the backplane; and a protection processing circuit coupled to the backplane and configured to: retrieve first selected monitoring data from the backplane in response to receipt of a first protection command, the first selected monitoring data including at least a portion of at least one of the first and second monitoring data, determine a value characterizing the first selected monitoring data, and transmit the determined value to the backplane.
 2. The system of claim 1, comprising a system interface circuit coupled to the backplane and configured to transmit the first protection command to the backplane, the first protection command identifying the first selected monitoring data for retrieval by the protection processing circuit.
 3. The system of claim 2, wherein the first protection command includes one or more set points corresponding to respective alarm conditions for the first selected monitoring data, and wherein the protection processing circuit is further configured to determine a status for the first selected monitoring data based upon a comparison of the set point to the determined value, and to transmit the determined status to the backplane.
 4. The system of claim 3, wherein the first selected monitoring data includes at least a portion of the first monitoring data and the second monitoring data.
 5. The system of claim 1, further comprising a first output circuit coupled to the backplane and configured to: retrieve the determined value from the backplane, and output a process control signal including a current or a voltage that is proportional to the determined value with reference to a predetermined scale.
 6. The system of claim 3, further comprising a second output circuit coupled to the backplane and configured to: retrieve second monitoring data from the backplane in response to receipt of a second protection command, and output the retrieved second monitoring data to at least one of a data storage device and a display; wherein the second protection command is transmitted to the backplane by the system interface circuit and identifies the second monitoring data; and wherein the second monitoring data includes at least a portion of at least one of the first operating parameter measurements and the second operating parameter measurements.
 7. The monitoring system of claim 1, wherein the backplane is a passive backplane.
 8. A system, comprising: a backplane configured to communicatively couple to a plurality of circuits, and to receive monitoring data from at least one circuit coupled to the backplane, wherein the monitoring data includes at least one of measurements of an operating parameter of a machine component acquired by a sensor and at least one value characterizing the monitoring data at a status time; a condition processing circuit coupled to the backplane and configured to retrieve a first selected portion of the monitoring data from the backplane in response to receipt of a conditioning command from a first network, and to transmit the retrieved first selected portion of the monitoring data to the first network, wherein the condition processing circuit is prohibited from transmitting information to the backplane.
 9. The system of claim 8, wherein the monitoring data includes a status of the measured operating parameter at a status time based upon the determined value, and wherein the conditioning command is operative to cause the condition processing circuit to: retrieve the status from the backplane, determine that the retrieved status matches a predetermined status, and retrieve at least one of first portion of the operating parameter measurements corresponding to a first predetermined time duration prior to the status time and a second portion of the operating parameter measurements corresponding to a second predetermined time duration after the status time.
 10. The system of claim 8, wherein the first network is not communicatively coupled to a second network, the second network being in communication with a control system operative to control the operating parameter of the machine component.
 11. The system of claim 10, comprising a system interface circuit coupled to the backplane and configured to receive a protection command from the second network, and to transmit the protection command to the backplane.
 12. The system of claim 11, comprising a protection processing circuit coupled to the backplane and configured to retrieve the operating parameter measurements from the backplane in response to receipt of the protection command, to determine the value based upon the retrieved operating parameter measurements, and to transmit the determined value to the backplane.
 13. The monitoring system of claim 8, wherein the backplane is a passive backplane.
 14. A method, comprising: communicatively coupling a first input circuit and a second input circuit to a backplane; transmitting, by the first input circuit, first monitoring data to the backplane, the first monitoring data representing measurements of a first operating parameter of a first machine component acquired by a first sensor; transmitting, by the second input circuit, second monitoring data to the backplane, the second monitoring data representing measurements of a second operating parameter of a second machine component acquired by a second sensor, different from the first sensor; communicatively coupling a protection processing circuit to the backplane; retrieving, by the protection processing circuit, first selected monitoring data from the backplane in response to receipt of a first protection command, the first selected monitoring data including at least a portion of at least one of the first and second monitoring data, determining, by the protection processing circuit, a value characterizing the first selected monitoring data, and transmitting, by the protection processing circuit, the determined value to the backplane.
 15. The method of claim 14, comprising: communicatively coupling a system interface circuit to the backplane, and transmitting the first protection command to the backplane, the first protection command identifying the first selected monitoring data for retrieval by the protection processing circuit.
 16. The method of claim 15, wherein the first protection command includes a set point corresponding to an alarm condition for the first selected monitoring data, and the method further comprises: determining, by the protection processing circuit, a status for the first selected monitoring data based upon the set point, and transmitting, by the protection processing circuit, the determined status to the backplane.
 17. The method of claim 15, comprising: communicatively coupling an output circuit to the backplane; retrieving, by the output circuit, second selected monitoring data from the backplane in response to receipt of a second protection command, and outputting, by the output circuit, the retrieved second monitoring data to an internal network in communication with a machine control system operative to control the first and second operating parameters of the first and second machine components; wherein the second protection command is transmitted to the backplane by the system interface circuit and identifies the second monitoring data; and wherein the second monitoring data includes at least a portion of at least one of the first operating parameter measurements and the second operating parameter measurements.
 18. The method of claim 17, comprising: communicatively coupling a condition processing circuit to the backplane and to a first network; retrieving, by the condition processing circuit, third selected monitoring data from the backplane in response to receipt of a conditioning command from an external network, different from the internal network, the third selected monitoring data including at least a portion of at least one of the first monitoring data, the second monitoring data, and the determined status; and transmitting, by the condition processing circuit, the retrieved third selected monitoring data to the external network; wherein the condition processing circuit is prohibited from transmitting information to the backplane.
 19. The method of claim 18, wherein the conditioning command is operative to cause the condition processing circuit to: retrieve a status for the first monitoring data at a status time from the backplane, determine that the retrieved status matches a predetermined status, and retrieve a portion of at least one of the first and second operating parameter measurements occurring adjacent in time to the status time.
 20. The method of claim 14, wherein the operating parameter includes at least one of vibration, position, speed, direction of motion, and eccentricity. 